Precipitate Characteristics and Mechanical Performance of Cast Mg-6RE-1Zn-xCa-0.3Zr (x = 0 and 0.4 wt%) Alloys

doi:10.1007/s40195-021-01269-3

Abstract

Abstract:

In this study, the Mg-4Y-1Gd-1Nd-xCa-1Zn-0.3Zr (x = 0 and 0.4 wt%) cast alloys with low rare earth concentration were prepared in different routes of heat treatments, and their microstructures and mechanical properties were investigated. The Mg-4Y-1Gd-1Nd-1Zn-0.4Ca-0.3Zr cast alloy with ultimate tensile strength (UTS) of 264 ± 7.8 MPa, tensile yield strength (TYS) of 153 ± 1.2 MPa and elongation to failure (EL) of 17.2 ± 1.2% was successfully developed by appropriate heat treatment. The improved mechanical performance was attributed to the combined strengthening effects of fine grains, Mg₂₄RE₅, $\beta ^{\prime}$, $\beta _{1}$, $\gamma ^{\prime}$ and LPSO phases. In the heat treatment process, cooling method of T4 treatment affected the microstructure, which consequently determined the mechanical properties air cooling, rather than water cooling, gave rise to the formation of $\gamma ^{\prime}$ phase in the alloy without Ca addition. However, Ca addition facilitated the formation of $\gamma ^{\prime}$ phase, and the $\gamma ^{\prime}$ phase precipitated in the alloy after T4 treatment either by water cooling or by air cooling, but the air cooling increased the number density of $\gamma ^{\prime}$ phase in comparison to the water cooling. Although the $\gamma ^{\prime}$ phase strengthened the studied alloys, the formation of $\gamma ^{\prime}$ phase inhibited the precipitatition of $\beta ^{\prime}$ and $\beta _{1}$ phases in the following T6 treatment, and consequently reduced the strengthening effect of $\beta ^{\prime}$ and $\beta _{1}$ phases. The results showed that the mechanical performance of the studied alloys was largely determined by the precipitation of $\gamma ^{\prime}$ phase, which was regulated by the Ca addition and the cooling method of T4 treatment.

Key words: Magnesium alloy, Microstructure, Mechanical properties, Rare earth, Heat treatment

Zijian Yu, Xi Xu, Baotian Du, Kang Shi, Ke Liu, Shubo Li, Xiuzhu Han, Tao Xiao, Wenbo Du. Precipitate Characteristics and Mechanical Performance of Cast Mg-6RE-1Zn-xCa-0.3Zr (x = 0 and 0.4 wt%) Alloys[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(4): 596-608.

Figures/Tables 14

Table 1 Chemical composition of the studied alloys

Alloys	Normal composition	Chemical composition (wt%)
Alloys	Normal composition	Y	Gd	Nd	Zn	Ca	Sr	Zr	Mg
WEZ421K	Mg-4Y-1Gd-1Nd-1Zn-0.3Zr	4.00	0.95	1.06	0.94	-	-	0.32	Bal
WEZX4210K	Mg-4Y-1Gd-1Nd-1Zn-0.4Ca-0.3Zr	4.16	1.12	1.18	1.00	0.37	-	0.39	Bal

Table 2 Processing history of the studied alloys

State	Processing history
As-cast	Melting at 760 °C ± 3 °C + Casting at 720 °C ± 3 °C
WCT4	T4-treated at 500 ± 3 °C for 10 h followed by water cooling
ACT4	T4-treated at 500 ± 3 °C for 10 h followed by air cooling
WCT6	WCT4 + aging at 200 °C ± 3 °C followed by water cooling
ACT6	ACT4 + aging at 200 °C ± 3 °C followed by water cooling

Fig. 1 OM images of as-cast a and c WEZ421K, b, d WEZX4210K alloys

Fig. 2 OM images of T4-treated WEZ421K and WEZX4210K alloys: WCT4-treated alloys a-d, ACT4-treated alloys e-h

Fig. 3 XRD results of T4-treated WEZ421K and WEZX4210K alloys in the various cooling conditions

Fig. 4 HAADF-STEM images of T4-treated WEZ421K alloy: WCT4-treated alloy a-f, ACT4-treated alloys g-m

Fig. 5 HAADF-STEM images of a Mg24RE5 phase in WEZ421K-WQT4 alloy, b Mg24RE5 phase, RE-riched phase and bulk LPSO phase in WEZ421K-ACT4 alloy

Fig. 6 HAADF-STEM images of T4-treated WEZX4210K alloy: WQT4-treated alloy a and b, ACT4-treated alloy c, d

Fig. 7 HAADF-STEM image and EDS mapping of γʹ phase in the WEZX4210K-ACT4 alloy

Fig. 8 HAADF-STEM images of a and b WEZ421K-WCT6, c and d WEZ421K-ACT6, e and f WEZX4210K-WCT6, g, h WEZX4210K-ACT6 alloys

Table 3 Mechanical properties, hardness and average grain sizes of the studied alloys

States	Alloys	Mechanical properties			GS (μm)
States	Alloys	TYS (MPa)	UTS (MPa)	EL (%)	GS (μm)
As-cast	WEZ421K	133 ± 6.1	239 ± 4.6	16.0 ± 1.5	21 ± 1.0
As-cast	WEZX4210K	134 ± 5.0	216 ± 2.6	9.0 ± 0.7	22 ± 0.6
WCT4	WEZ421K	128 ± 1.2	244 ± 0.5	28.9 ± 1.5	32 ± 1.3
WCT4	WEZX4210K	129 ± 2.2	257 ± 4.6	21.8 ± 2.1	28 ± 3.2
ACT4	WEZ421K	130 ± 2.6	246 ± 3.7	25.6 ± 2.7	39 ± 3.0
ACT4	WEZX4210K	139 ± 2.8	249 ± 3.7	15.5 ± 1.3	27 ± 1.4
WCT6	WEZ421K	135 ± 0.5	249 ± 0.5	26.4 ± 2.5	-
WCT6	WEZX4210K	153 ± 1.2	264 ± 7.8	17.2 ± 1.2	-
ACT6	WEZ421K	135 ± 2.5	260 ± 2.8	26.9 ± 1.0	-
ACT6	WEZX4210K	140 ± 0.5	234 ± 1.2	11.1 ± 0.2	-

Fig. 9 Age-hardening curves of T6-treated WEZ421K and WEZX4210K alloys: a WCT6-treated alloy, b ACT6-treated alloy

Fig. 10 Stress-strain curves of WEZ421K and WEZX4210K alloys in the a as-cast, b T4-treated, c T6 treated conditions

Fig. 11 Schematic diagrams of observed microstructures in WEZ421K and WEZX4210K alloys under different heat treatment conditions

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